Automatic transmission

ABSTRACT

Automatic transmission device comprising: a number n of planetary gears arranged coaxially in a row, each planetary gear comprising a sun wheel, a planetary carrier carrying pivoted planetary wheels and an annulus gear, an input column connected to a sun wheel of a first planetary gear of the row of planetary gears, a general gear positioned adjacent to the row of planetary gears next to a last planetary gear, n mediator gears, each mounted on an output column, and connected to the output column via a freewheel assembly such that the mediator gears, are freely rotatable in one direction relative to the output column, each mediator gear being in engagement with one of the planetary wheels, wherein a planetary carrier of the last planetary gear is fixed to the general gear, and a planetary carrier of each but the last planetary gear being connected to a sun wheel of a following planetary gear positioned adjacently towards the last planetary gear, wherein rotation of any of the mediator gears can be stopped selectively.

INVENTION BACKGROUND

This automatic transmission device works on decreasing the velocity emerging out of it to get a low speed and a large car torque. Among the problems related to previous inventions are its complexity due to the large number of components, high maintenance cost, in addition to the leakage of some power and energy via clutches clinging to each other to increase its temperature.

OVERALL DESCRIPTION OF THE INVENTION

One of the characteristics of this invention is segmentation of the power and distributing it through one or more planetary gear of which the device is composed that transmit all energy without any leakage of torque, and each of the gear planets is easily controlled whenever we want to increase the velocity and decrease the torque emerging out of the transmitting device. The device is also characterized by its relatively small size, few homogeneous components, easy maintenance, and no energy penetration. A remarkable characteristic is that the gears are always connected to each other (interlocked) and there is no bond break between transits. It also combines the characteristics of both the conventional and automatic transit device at the same time.

The invention is characterized by an automatic transmission device according to claim 1.

A transmission ratio between the general gears and the corresponding main gears can be between 0.3 and 0.9, in particular 0.5.

In a preferred embodiment, the automatic transmission device comprises a first final gear which is coaxially mounted to the output column and a second final gear which is in revolving contact with the first final gear. The dimensions of the first final gear and the second final gear may be selected to determine a maximum rotation velocity of the output column.

The invention is distinguished by the existence of a number of planetary gears connected to each other in the following way (1), (2), and (3) or more [the components of each is presented in FIG. C: (22), (23), and (24)] and the general gear (4) which divide the force coming to it from input column (9) to rotate output column (10) at a low speed and strong torque when all the gears are working and a high speed and low torque when one or more of the gears are controlled (stopped).

The invention is distinguished by the existence of a number of devices functioning as a mediator between gears (5), (6), and (7) and the output column (10) so the movement will be in one direction. In case some of these gears stop working, (10) will continue rotating because of the rotation of the other working gears.

The various diameters of gears (4), (8), (17), and (18) decrease the final transmission ratio for each group which is usually double the previous one to meet the requirements.

Gears (19) and (20) of various diameters balance the final velocity at the end of each group to be suitable with the minimum velocity, maximum velocity with the velocity of the input column (9).

It is distinguished by two links connected to each other: the first on (9) and the other on (10) whereby (10) drives (9) if it is faster than it and the opposite is not true due to a device working in one direction. This connection is to provide the adverse energy.

BRIEF ILLUSTRATION OF THE FIGURES

The device's specification and features will be elaborated more carefully by the description below of Method of working for an automatic transmission by dividing the energy and then collection

FIG.(A)

(1), (2), and (3) represent planetary gears

(4) and (8) general gears

(5), (6), and (7) represent gears working in one direction on Column output (10)

(9) Entering column for movement (input column)

(10) Exiting column for movement (output column)

FIG. (B)

(1), (2), (3), (11), (13), (15) represent planetary gears

(4), (8), (17) and (18) are general gears

(5), (6), (7), (12), (14) and (16) represent gears working in one direction on Column output (10)

(9) Entering column for movement (input column)

(10) Exiting column for movement (output column)

(19) And (20) gears of various diameters to increase velocity

FIG. (C)

(10) exiting column for movement (output column)

(21) device working in accordance with the gear movement in one direction with (10)

(22), (23) and (24) planetary gear unit elements

DETAILED DESCRIPTION

It is a device for transmitting automatic movement working on dividing and distributing the energy coming from input column (9) through three planetary gears as in figure (A) and they are (1), (2), and (3) where (1) receives energy through one of its three components (22), (23), and (24) and the energy is then divided between the other two components. Where one of these components is related to (5) on output column (10), the other transmits what has remained of the energy to (2) and (3). The same will happen with (2) and (3) until what has left of energy reaches (4) which is a general gear and not a planetary gear unit.

By this way, the energy is divided into four parts and the output column (10) moves at a lower speed than input column (9) and with a strong torque. Thus, the speed of (10) is calculated by dividing this of (9) by four.

So far, we have discussed the procedure of dividing the energy that results in a low speed and a strong torque. Now let's see the procedure of restricting energy where we halt one gear (5) and so the planetary gear (1) related to it stops and all the energy comes out of it and gets restricted between the planetary gears (2) and (3) and the general gear (4). Thus, the speed of (10) is calculated by dividing that of (9) by three.

When we halt gear (6), the planetary gear (2) related to it stops and all the energy comes out of it and becomes restricted between the planetary gear (3) and the general gear (4). Thus, the speed of (10) is calculated by dividing that of (9) by two.

When we halt gear (7), the planetary gear (3) related to it stops and all the energy comes out of it and becomes restricted within the general gear (4). Thus, the speed of (10) is calculated by dividing that of (9) by one. This means that the speed of (10) is approximately equivalent to that of (9) paying attention to the fact that the diameter of gear (4) must be smaller than that of (8) so this transmission will be of a desired and not a strong remarkable impact.

The procedure of stopping and controlling the gears could happen in several ways. It could be done by using a belt exalting pressure on a soft area of the gear or by an iron tongue coming out to cling in a slot on the gear.

To benefit more from the device, each group must be connected to the other to get a more appropriate transmission movement. This can be seen in figure (B) where the first group is represented by the planetary gears (1), (2), and (3) and the second group by the planetary gears (11), (13), and (15). A mutual control process is preferred where at one time a gear from the first group is controlled and at another time a gear from the second group is controlled.

FIG. (B) gives us the following illustrations:

If we suppose that the speed of (9) is actual eight rotations, then the number of (10) rotations are:

When all planetary gears work, the speed of (10) is 0.5 rotations

When we stop gear (5), the speed of (10) is 0.66 rotations.

When we stop gear (12), the speed of (10) is 0.88 rotations.

When we stop gear (6), the speed of (10) is 1.33 rotations.

When we stop gear (14), the speed of (10) is 2 rotations.

When we stop gear (7), the speed of (10) is 4 rotations.

By changing the diameters of the gears (4) and (8), the number of rotations in this phase decreases from 4 to 2.8 to adapt with the required transmission ratios.

When we stop gear (16), the speed of (10) is 5.6 rotations. By changing the diameters of the gears (17) and (18), the number of rotations in this phase decreases from 5.6 to 4 to adapt with the required transmission ratios.

So column input (9) which supposedly moves 8 rotations gives us the following 7 transmissions: 0.5, 0.66, 0.88, 1.33, 2, 2.8, 4

Finally, the speed of (10) must be increased by gears of various diameters (19) and (20) by a ratio of 1:4 so the ration transmissions become:

2, 2.64, 3.52, 5.32, 8, 11.2, 16

So, the input column (8 rotations) gives 2 rotations when all planetary gears work and 16 rotations when all gears stop.

All what was shown above of illustrating examples and calculations are just meant to present one aspect of the device's work and could be changed according to the gear sizes to meet the requirements.

All gears working on (10) are related to it in only one direction. In case, the speed of the column exceeds that of the gear, this is not to affect the gear as it is possible that the gear will stop moving during the rotation of the column. However, the opposite is not true. When the speed of the gear exceeds that of the column, the column is forced to rotate with the gear and this is because a device working in only one direction (21) located between the gear and output column (10). It is because of (21) that the column never stops when we control one of the gears on it.

Output Column (10) is linked to input column (9) by two gears and there is a valve between of the two gears and the column on which it is located in a way that there will be no impact when speed of (9) exceeds that of (10). However, if the speed of (10) exceeds that of (9), column (10) drives column (9) to provide the adverse energy.

To summarize, the invention is about an automatic transmission device that works on decreasing the velocity emerging out of it. This process is carried out by dividing and distributing of energy over a number of consecutive planetary gears (1), (2), (3), and the normal gear (4). Each of these gears is connected to gears (5), (6), (7), and (8) located on output column (10) whereby each of these gears take some quantity of the energy and transmits the rest of it to the subsequent gears through one of the three components of the planetary gears unit. Each of the gears is composed of three components (22), (23), and (24); (22) is for transmitting energy, (23) is to allow the transmission of some energy to output column (10), and (24) is to allow the transmission of the remaining energy to other planetary gears. In order to increase the velocity emerging out of the device, one of the gears is stopped by halting its component that is transmitting energy to (10). Hence, the force is distributed to other planetary gears until all gears are stopped and the force is transmitted from input column (9) to output column (10) through (4) and (8) and passing through all the planetary gears to get a high velocity and low torque.

In order to decrease the velocity, we would release the third component of each gear that is related to output column in order to get a low velocity and high torque from the output column.

With this invention we have an automatic transmission device with strong enduring reliability without losing control over velocity and torque and without complicating it with many components which makes it easier for maintenance. It could work in cars, trucks, heavy equipment, and other motors. 

1. Automatic transmission device comprising: a number n of planetary gears arranged coaxially in a row, each planetary gear comprising a sun wheel, a planetary carrier carrying pivoted planetary wheels and an annulus gear, an input column connected to a sun wheel of a first planetary gear of the row of planetary gears, a general gear positioned adjacent to the row of planetary gears next to a last planetary gear, n mediator gears, each mounted on an output column and connected to the output column via a freewheel assembly such that the mediator gears are freely rotatable in one direction relative to the output column; each mediator gear being in engagement with one of the planetary wheels, wherein a planetary carrier of the last planetary gear is fixed to the general gear, and a planetary carrier of each but the last planetary gear being connected to a sun wheel of a following planetary gear positioned adjacently towards the last planetary gear, wherein rotation of any of the mediator gears can be stopped selectively.
 2. Automatic transmission device according to claim 1, characterized in that a transmission ratio of the general gears and corresponding main gears is between 0.3 and 0.9.
 3. Automatic transmission device according to claim 1, characterized by a first final gear coaxially mounted to the output column, and a second final gear which is in revolving contact with the first final gear, the dimensions of the first final gear and the second final gear being selected to determine a desired rotation velocity of the output column.
 4. Automatic transmission device according to claim 2, characterized by a first final gear coaxially mounted to the output column, and a second final gear which is in revolving contact with the first final gear, the dimensions of the first final gear and the second final gear being selected to determine a desired rotation velocity of the output column.
 5. Automatic transmission device according to claim 1, characterized in that a transmission ratio of the general gears and corresponding main gears is 0.5.
 6. Automatic transmission device according to claim 5, characterized by a first final gear coaxially mounted to the output column, and a second final gear which is in revolving contact with the first final gear, the dimensions of the first final gear and the second final gear being selected to determine a desired rotation velocity of the output column. 